KR20230016895A - Energy-saving heat supply system for food reduction facilities - Google Patents

Abstract

The present invention provides an energy-saving core heat supply device for a food reduction facility that enables heating heat and hot air to be simultaneously supplied to the center and inside of food waste during agitation and drying for reducing the amount of food waste filled in a drum, so that the drying time for reducing food waste can be greatly reduced, and electric energy can be greatly reduced by minimizing heat loss.

Description

Energy-saving heat supply system for food reduction facilities}

The present invention relates to an energy-saving core heat supply device for a food reduction facility, and more particularly, to simultaneously supply heating heat and hot air to the center and inside of food waste during agitation and drying to reduce food waste, It relates to an energy-saving core heat supply device for a food reduction facility that maximizes the reduction of waste and at the same time significantly reduces electrical energy.

In general, there is a trend of increasing the amount of food waste thrown away in the process of selling and distributing various agricultural and livestock products, including food waste thrown away at home or restaurants.

Accordingly, moisture contained in the food waste not only contaminates the area around the food waste collection box, but also causes civil complaints due to odor.

Moreover, according to the volume-rate system that charges a fee according to the total amount of food waste generated, there is a problem in that the collection processing cost paid by each household and restaurant increases, which acts as a burden.

In order to solve the above problems, various facilities and devices that can reduce the volume of food waste by drying it using heating or the like have been released.

Conventional facilities and devices for reducing food waste essentially include a drum filled with food waste and an agitator rotatably mounted in the drum to agitate the food waste.

In addition, most of the conventional facilities and devices for reducing food waste are a method of heating and drying food waste, supplying energy through heating the surface of the drum by winding a band heater outside the drum, or manufacturing a double tank structure outside the drum A method of heating heating medium oil to dry food waste by conduction heat and a method of supplying hot air from a hot air device disposed outside the drum to the inside of the drum are adopted.

However, in the case of drying the food waste by directly attaching a heater to the outer surface of the drum, the heater attached to the outer surface of the drum heats only the contact portion of the food waste filled in the drum, thereby heating the core portion of the food waste (food waste). There is a problem in that the heat is not smoothly transferred to the center and the inside of the trash, so it takes too long to reduce the amount of food waste, and the heater heat attached to the surface of the drum is dissipated to the outside of the drum. Since the loss of the heat source is very large, there is a problem in that the consumption of electricity for providing energy is greatly increased.

Similarly, in the case of a method of supplying hot air from a hot air device disposed outside the drum to the inside of the drum, as the hot air flowing into the drum heats the upper surface of the food waste, the core portion of the food waste (food waste) There is a problem in that the heat is not smoothly transferred to the center and the inside), so the drying time for reducing food waste is too long, and the consumption of electric energy due to the loss of surface dissipation energy of the hot air generator for supplying the hot air There is a problem that increases greatly.

Registered Patent Registration No. 10-2261305 (2021.06.01) Registered Patent Registration No. 10-0943032 (2010.02.10)

The present invention has been made to solve the above conventional problems, and when stirring and drying for reducing the amount of food waste filled in the drum, heating heat and hot air can be simultaneously supplied to the center and inside of the food waste, An object of the present invention is to provide an energy-saving core heat supply device for a food reduction facility that can significantly reduce the drying time for reducing waste and minimize heat loss to greatly reduce electrical energy.

In order to achieve the above object, the present invention includes: a drum filled with food waste; a hollow rotary shaft having both ends rotatably connected to both side surfaces of the drum and arranged along the left and right longitudinal directions within the drum; a plurality of hollow stirring blades that are communicatively mounted on the hollow rotary shaft to agitate the food waste filled in the drum; a nozzle body extending from an end of the agitating blade and having a nozzle hole for discharging hot air through which hot air is discharged into the drum; a heater line introduced through an opening on one side of the hollow rotary shaft and disposed within the hollow rotary shaft; a hot air supply fan connected to the other open part of the hollow rotary shaft and supplying hot air to the nozzle body through the hollow rotary shaft and the hollow stirring blades; And a driving unit connected to the other side of the hollow rotary shaft to transmit rotational force to the hollow rotary shaft and the hollow stirring blades; Including, when the hollow rotating shaft and the hollow stirring blades rotate to agitate the food waste filled in the drum, heating heat according to the operation of the heater line is transferred from the hollow rotating shaft to the center of the food waste. Provided is an energy-saving core heat supply device for a food reduction facility, characterized in that the hot air driven by the hot air supply fan is transferred to the inside of the food waste through the nozzle hole for discharging hot air of the nozzle body.

Preferably, the nozzle hole for discharging hot air of the nozzle body is formed on the rear wall surface of the nozzle body opposite to the moving direction of the food waste according to the stirring operation of the hollow agitating blade.

In addition, a valve hole opened and closed by a ball falling due to its own weight is provided at the end of the hollow stirring blade, so that when the hollow stirring blade is positioned on the upper side of the hollow rotating shaft, the ball falls. When the valve hole is closed and the hollow agitation blade is located on the lower side of the hollow rotary shaft, a check valve is installed so that the valve hole is opened by the drop of the ball.

In addition, in order to prevent twisting of the heater line when the hollow rotary shaft rotates, an outer end of the heater line is connected to the power supply line by a mercury slip ring joint mounted on the outside of one side of the drum.

In addition, a rotary joint for preventing transmission of rotational force to the hot air supply fan is connected between the other end of the hollow rotary shaft extending to the outside through the other side of the drum and the discharge part of the hot air supply fan.

Preferably, four hollow stirring blades form a set along the circumferential direction of the hollow rotating shaft and are mounted in an array of 90 degrees, and the heat of the heater line is transferred to the hollow rotating shaft between the hollow stirring blades. It is characterized in that a plurality of heat sinks for dissipating heat to the inside are further mounted.

Through the means for solving the above problems, the present invention provides the following effects.

First, when rotating and stirring the hollow rotating shaft and the hollow stirring blades for reducing food waste, the heating heat according to the operation of the heater line is transferred from the hollow rotating shaft to the center of the food waste, and at the same time, the hot air due to the driving of the hot air supply fan By supplying the hot air to the inside of the food waste through the nozzle hole for discharging the hot air of the nozzle body, the drying time for reducing the amount of food waste can be greatly reduced compared to the conventional method of supplying heater heat or hot air to the outer portion of the food waste. .

Second, as the heating heat according to the operation of the heater line and the hot air according to the operation of the hot air supply fan are all supplied to the core part (center and inside) of the food waste, heat loss dissipated to the outside can be minimized, and accordingly Not only can the drying time for the reduction of food waste be greatly reduced, but also the electric energy can be greatly saved.

Third, four hollow stirring blades are mounted in a 90-degree arrangement along the circumferential direction of the hollow rotating shaft, and a plurality of heat sinks for radiating heat from the heater line to the inside of the food waste are installed on the hollow rotating shaft between the hollow stirring blades. By installing more, it is possible to greatly reduce the drying time for the reduction of food waste and also to greatly save electric energy.

1 is a front cross-sectional view showing an energy-saving core heat supply device of a food reduction facility according to the present invention;
2 is a side cross-sectional view showing a nozzle body formed on a hollow stirring blade of an energy-saving core heat supply device of a food reduction facility according to the present invention;
Figure 3 is a front cross-sectional view showing the operating state of the energy-saving core heat supply device of the food reduction facility according to the present invention;
4 is a front cross-sectional view showing another embodiment of an energy-saving core heat supply device for food reduction equipment according to the present invention;
5 is a cross-sectional view taken along line BB of FIG. 4;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a front cross-sectional view showing an energy-saving core heat supply device of a food reduction facility according to the present invention, and FIG. 2 is a hollow stirring blade of an energy-saving core heat supply device of a food reduction facility according to the present invention. As a side cross-sectional view showing the nozzle body to be, reference numeral 10 indicates a drum.

The drum 10 has a structure in which a lid is hingedly mounted on the top so that food waste is filled for reduction and drying, and a discharge door is installed at the bottom to discharge food waste that has been reduced and dried. there is.

Inside the drum 10, a hollow rotary shaft 20 is installed rotatably.

That is, both ends of the hollow rotary shaft 20 are rotatably connected to both side surfaces of the drum 10, so that the hollow rotary shaft 20 is arranged in the drum 10 along the left and right longitudinal directions.

In addition, a plurality of hollow stirring blades 30 for agitating the food waste filled in the drum 10 are communicatively mounted on the outer diameter of the hollow rotating shaft 20 .

Preferably, the plurality of hollow stirring blades 30 are regularly or irregularly mounted to communicate with the hollow rotary shaft 20 while being perpendicular to the hollow rotary shaft 20 .

In addition, a nozzle body 50 having a nozzle hole 52 for discharging hot air for discharging hot air into the drum 10 is extended at the end of the hollow stirring blade 30 .

If, when the hollow stirring blades 30 rotate and agitate the food waste, the nozzle hole 52 for discharging hot air of the nozzle body 50 is formed in the direction in which the food waste is stirred, small pieces of food waste The nozzle hole 52 for hot air discharge is blocked, and the hot air discharge is not performed properly.

In order to solve this problem, the nozzle hole 52 for discharging hot air of the nozzle body 50, as can be seen in FIG. 2, is positioned opposite to the moving direction of the food waste according to the stirring operation of the hollow stirring blades 30. It is formed on the rear wall surface of the nozzle body 50.

Accordingly, when the hollow stirring blades 30 rotate and agitate the food waste, a space spaced apart from the nozzle body 50 is instantaneously formed at a position opposite to the agitating direction of the food waste, so that the nozzle body 50 ) The hot air can be easily discharged into the drum through the nozzle hole 52 for discharging hot air.

In addition, a check valve 40 for supplying and blocking hot air is mounted in the end of the hollow stirring blade 30, and the check valve 40 includes a ball 42 falling by its own weight, It consists of a valve hole 44 opened and closed by a ball 42.

More specifically, a valve hole 44, which is one component of the check valve 40, is formed at the end of the hollow stirring blade 30 that passes through the nozzle body 50, and the valve hole 44 The ball 42 is placed on the outside to be opened and closed.

Accordingly, when the hollow stirring blades 30 are located on the upper side of the hollow rotating shaft 20, the valve hole 44 is closed by the fall of the ball 42, so that the supply of hot air to the nozzle body 50 is blocked. On the other hand, when the hollow stirring blades 30 are located on the lower side of the hollow rotary shaft 20, the valve hole 44 is opened by the fall of the ball 42, so that the hot air blows through the nozzle body 50 can flow easily.

At this time, a hot air supply fan 70 for supplying hot air to the nozzle body 50 through the hollow rotary shaft 20 and the hollow stirring blades 30 is located at the other open part of the hollow rotary shaft 20. Connected.

Preferably, the other end of the hollow rotary shaft 10 extending to the outside through the other side surface of the drum 10 so that rotational force is not transmitted to the hot air supply fan 70 when the hollow rotary shaft 20 rotates, and Between the discharge parts of the hot air supply fan 70, a rotary joint 72 like a kind of bearing is connected.

Therefore, after the hot air according to the operation of the hot air supply fan 70 is supplied to the nozzle body 50 through the hollow rotating shaft 20 and the hollow stirring blades 30, the nozzle body 50 is used for discharging hot air Food waste may be discharged into the inside of the drum 10 through the nozzle hole 52 .

In addition, a heater line 60 for heating and drying the central part of the food waste filled in the drum is arranged inside the hollow rotary shaft 20 .

More specifically, the heater line 60 is drawn in through one side opening of the hollow rotary shaft 20 and circulated and discharged within the hollow rotary shaft 20, so that heating heat according to the operation of the heater line 60 is generated in the hollow rotary shaft 20. It may diverge from the rotating shaft 20 toward the center of the food waste.

Preferably, in order to prevent twisting of the heater line 60 when the hollow rotary shaft 20 rotates, an outer end of the heater line 60 is mounted on the outside of one side of the drum 10 at a mercury slip ring joint. It is connected to the power supply line 64 by 62.

On the other hand, in order to transmit rotational force to the hollow rotary shaft 20 and the hollow stirring blades 30, a driving unit 80 made of a conventional motor and gearbox is connected to the other side of the hollow rotary shaft 20.

Here, the operation flow of the energy-saving core heat supply device of the food reduction facility according to the present invention having the above configuration is as follows.

3 is a front cross-sectional view showing an operating state of the energy-saving core heat supply device of the food reduction facility according to the present invention.

First, food waste to be reduced and dried is filled in the drum 10 .

Subsequently, the hollow rotating shaft 20 and the hollow stirring blades 30 in the drum 10 are rotated by the drive of the driving unit 80 to agitate the food waste.

In addition, since the heater line 60 is heated by supplying power to the heater line 60, the heating heat according to the operation of the heater line 60 is transferred from the hollow rotary shaft 20 to the center of the food waste. By dissipation, heating and drying of the center (core) of the food waste can be performed.

In addition, after the hot air according to the operation of the hot air supply fan 70 is supplied to the nozzle body 50 through the hollow rotating shaft 20 and the hollow stirring blades 30, the hot air is discharged from the nozzle body 50 As the food waste is discharged into the inside of the drum 10 through the nozzle hole 52, the inside (core part) of the food waste can be heated and dried with hot air.

At this time, when the hollow stirring blades 30 are positioned on the upper side of the hollow rotating shaft 20 while agitating and rotating and are positioned on the upper surface of the food waste, the valve hole 44 is opened by the fall of the ball 42. By being closed, the supply of hot air to the nozzle body 50 is cut off, and accordingly, it is possible to block the hot air from being discharged to the outside instead of the inside of the food waste.

On the other hand, when the hollow agitation blades 30 are positioned on the lower side of the hollow rotary shaft 20 while stirring and rotating and are located inside the food waste, the valve hole 44 is opened by the fall of the ball 42. As a result, the hot air can easily flow into the nozzle body 50, and accordingly, the hot air is discharged to the inside of the food waste through the nozzle hole 52 for discharging hot air of the nozzle body 50, and the inside of the food waste (core part) Hot air heating and drying for the can be easily achieved.

In this way, when the hollow rotary shaft 20 and the hollow stirring blades 30 rotate to agitate the food waste filled in the drum 10, the heating heat according to the operation of the heater line 60 is generated in the hollow shape. At the same time, the hot air according to the driving of the hot air supply fan 70 is delivered to the inside of the food waste through the hot air discharge nozzle hole 52 of the nozzle body 50. By doing so, it is possible to greatly reduce the drying time for reducing the food waste compared to the conventional method of supplying heater heat or hot air to the outer portion of the food waste.

In addition, as the heating heat according to the operation of the heater line 60 and the hot air according to the operation of the hot air supply fan 70 are both supplied to the core part (center part and inside) of the food waste, heat loss dissipated to the outside is reduced. Accordingly, drying time for reducing food waste can be greatly reduced, and electric energy can be greatly reduced.

On the other hand, according to another embodiment of the present invention, the hollow stirring blades 30 mounted on the hollow rotary shaft 20 are configured as a set of four or more, and the heat sink 90 is further mounted on the hollow rotary shaft 20. Thus, it is possible to increase the mixing efficiency of the food waste and at the same time further improve the drying efficiency of the food waste.

4 is a front cross-sectional view showing another embodiment of an energy-saving core heat supply device for a food reduction facility according to the present invention, and FIG. 5 is a cross-sectional view taken along line B-B in FIG.

As shown in Figures 4 and 5, according to another embodiment of the present invention, four hollow stirring blades 30 form a set along the circumferential direction of the hollow rotary shaft 20 and are mounted in an array of 90 degrees. And, the four hollow stirring blades 30 are mounted at predetermined intervals along the longitudinal direction of the hollow rotary shaft 20.

Accordingly, when the four hollow stirring blades 30 agitate and rotate, at least two or more are located on the lower side of the hollow rotating shaft 20 and at the same time are located inside the food waste, so that the two or more hollow stirring blades As the valve hole 44 is opened by the fall of each ball 42 included in the ball 30, hot air can be discharged from the nozzle body 50 of the at least two or more hollow stirring blades 30 to the inside of the food waste. Accordingly, hot air heating and drying of the inside (core portion) of the food waste can be further maximized.

In addition, according to the embodiment according to the present invention, a plurality of heat sinks 90 for radiating heat from the heater line 60 to the inside of the food waste are provided on the hollow rotating shaft 20 between the hollow stirring blades 30. They are further mounted at predetermined intervals.

Accordingly, the heating heat according to the operation of the heater line 60 is transferred from the hollow rotary shaft 20 to the center of the food waste and at the same time transferred to the inside of the food waste through the heat sink 90, so that the center of the food waste ( Heating and drying of the core part) can be performed more easily.

10: drum
20: hollow rotary shaft
30: hollow stirring blades
40: check valve
42: ball
44: valve hole
50: nozzle body
52: nozzle hole for hot air discharge
60: heater line
62: mercury slip ring joint
64: power supply line
70: hot air supply fan
72: rotary joint
80: driving unit
90: heat sink

Claims (6)

a drum 10 filled with food waste;
a hollow rotary shaft 20 having both ends rotatably connected to both sides of the drum 10 and arranged along the left and right longitudinal directions within the drum 10;
a plurality of hollow stirring blades 30 that are communicatively mounted on the hollow rotating shaft 20 to stir food waste filled in the drum 10;
a nozzle body 50 extending from the end of the stirring blade 30 and having a nozzle hole 52 for discharging hot air to discharge hot air into the drum 10;
a heater line 60 introduced through an opening on one side of the hollow rotary shaft 20 and disposed within the hollow rotary shaft 20;
A hot air supply fan 70 connected to the other open part of the hollow rotating shaft 20 and supplying hot air to the nozzle body 50 through the hollow rotating shaft 20 and the hollow stirring blades 30; and
A driving unit 80 connected to the other side of the hollow rotary shaft 20 to transmit rotational force to the hollow rotary shaft 20 and the hollow stirring blades 30;
including,
When the hollow rotary shaft 20 and the hollow stirring blades 30 rotate to agitate the food waste filled in the drum 10, heating heat according to the operation of the heater line 60 is generated by the hollow rotary shaft 20 ) to the center of the food waste, and at the same time, the hot air according to the driving of the hot air supply fan 70 is transmitted to the inside of the food waste through the nozzle hole 52 for discharging hot air of the nozzle body 50. An energy-saving core heat supply device for a food reduction facility.
The method of claim 1,
The nozzle hole 52 for discharging hot air of the nozzle body 50 is formed on the rear wall surface of the nozzle body 50, which is opposite to the moving direction of the food waste according to the agitation operation of the hollow stirring blades 30. Characterized by an energy-saving core heat supply device for a food reduction facility.
The method of claim 1,
A valve hole 44 opened and closed by a ball 42 falling by its own weight is provided at the end of the hollow stirring blade 30, so that the hollow stirring blade 30 is a hollow rotary shaft. The valve hole 44 is closed by the fall of the ball 42 when it is located on the upper side of the 20, and when the hollow stirring blades 30 are located on the lower side of the hollow rotary shaft 20, the ball 42 An energy-saving core heat supply device for a food reduction facility, characterized in that a check valve 40 is mounted so that the valve hole 44 is opened by falling.
The method of claim 1,
In order to prevent twisting of the heater line 60 when the hollow rotary shaft 20 rotates, the outer end of the heater line 60 is attached to the mercury slip ring joint 62 mounted on the outside of one side of the drum 10. Energy-saving core heat supply device for food reduction equipment, characterized in that connected to the power supply line 64 by the.
The method of claim 1,
Between the other end of the hollow rotary shaft 10 extending to the outside through the other side of the drum 10 and the discharge part of the hot air supply fan 70, there is a rotary joint for preventing transmission of rotational force to the hot air supply fan 70. Energy-saving core heat supply device for food reduction equipment, characterized in that (72) is connected.
The method of claim 1,
Four hollow stirring blades 30 form a set along the circumferential direction of the hollow rotating shaft 20 and are mounted in a 90 degree array, and the hollow rotating shaft 20 between the hollow stirring blades 30 has An energy-saving core heat supply device for a food reduction facility, characterized in that a plurality of heat sinks (90) are further mounted to dissipate heat from the heater line (60) to the inside of the food waste.

Images